Small retrofocus type super wide-angle objective lens system

ABSTRACT

A small retrofocus type super wide-angle objective lens system having an aperture ratio of 1:3.5 and a picture angle up to 100*, with a front divergent lens group A and a rear convergent lens group B, said front divergent lens group A consisting of front and rear lens groups A1 and A2, said front lens group A1 consisting of a positive meniscus first component L1 that has its object side a convex surface and two negative meniscus second and third components L2 and L3, said rear lens group A2 consisting of a positive lens fourth component L4 and a negative meniscus fifth component L5, and said rear convergent lens group B consisting of two positive lens sixth and seventh components L6 and L7, a negative lens eighth component L8, and two positive lens ninth and tenth components L9 and L10, and which is defined by the following three conditions, i.e.

United S r V 1111 3,877,795

Yamashita 1 Apr. 15, 1975 1 1 SMALL RETROFOCUS TYPE SUPER I picture angle up to 100, with a front divergent lens WIDE-ANGLE OBJECTIVE LENS SYSTEM group A and a rear convergent lens group B, said front diver ent lens rou A consistin of front and rear [75] lnventor: Nobuo Yamashlta, Tokyo, Japan lens g p Al i :2 said ,frontglens g p l com [73] Assignee: Olympus Optical Company Limited, sisting of a positive meniscus first component L that Tokyo, Japan has its object side a convex surface and two negative meniscus second and third components L and L said [22] Filed May 1973 7 rear lens group A consisting of a positive lens fourth [21] Appl. No.: 356,192 component L and a negative meniscus fifth component L and said rear convergent lens group B consisting of two positive lens sixth and seventh components [30] Foreign Apphcano-n Pnonty Data L and L a negative lens eighth component L and May 4, 1972 Japan 47-44326 two positive lens ninth and tenth components L9 and e L and which is defined b the followi three cond- 52 U.S. (:1 350/214; 350/176 ff Le y [51] Int. Cl G02b 9/00; G02b l/OO [58] Field of Search 350/214, 176

f1 [56] References Cited 1) 0.2 f 08 45 UNlTED STATES PATENTS 2) 5f r2 on 3,549,241 12/1970 Mori 350/214 X f f 3,572,901 3/1971 Mori 350/214 X 3,740,120 6/1973 1211111 350/214 3,748,021 7/1973 Tajima et a1 350/214 Wherem fm Is a composlte focal length of the first,

second and third components L L and L f is an primary p sacher overall focal length of the total lens system, r is a ra- Atmmey, Agent, Firm HaSe1tine, Lake & waters dius of curvature of the rear surface of the first component L and Ed is the sum of the air spaces and axial thicknesses of the sixth component L to the 57 RACT tenth component L of the rear convergentlens group A small retrofocus type super wide-angle objective lens system having an aperture ratio of 1:3.5 and a 5 Claims 12 Drawing Figures PATENTEDAPR 1 sum 3, 877, 79s sum 2 95 5 PATENIEIJAPRI sums 3 877. 795

SHKU 0F 5 Transverx sphericd aberraf/on Coma a! -50 0 0.2 7 Como a! 4/ SMALL RETROFOCUS TYPE SUPER WIDE-ANGLE OBJECTIVE LENS SYSTEM This invention relates to a small retrofocus type super wide-angle objective lens system having an aperture ratio of 113.5 and a picture angle up to 100.

A wide-angle lens for use in single-lens reflex cameras comprises a reflecting mirror disposed between the lens system and a film surface so that provision must be made of a back focal length which is longer than a given length. In a retrofocus type lens system. in general. if the lens system is made short in focal length. that is. wide in angle of view. the back focal length becomes short. ln order to make the back focal length long. the front divergent lens group provided for the lens system must be separated long enough from the rear convergent lens group or each of these front and rear lens groups must have a sufficiently high refractive power. In the former design. the overall length of the lens system becomes long. and as a result. the lens system becomes large in size.

The small super wide-angle lens system according to the invention. therefore. makes use of the above mentioned latter design.

In the retrofocus type lens systems. in general. the high refractive power of the front and rear lens groups thereof is capable of making the back focal length long. but causes the negative distortion. astigmatisms and comas to be increased.

The object of the invention. by adopting suitable dimensions for successive components and suitable combination and arrangement thereof. is to provide a small retrofocus type super wide-angle objective lens system having an aperture ratio of 1:35. a picture angle up to 100 and a long back focal length and yet having significantly corrected various aberrations and thus is adapted for use in photographic cameras.

In the present invention. it has been found that the foregoing disadvantage can be obviated. with obtention of a small and significantly corrected super wide-angle objective lens system. by the provision of a novel lens type comprising a front divergent lens group consisting of five components and a rear convergent lens group consisting also of five components.

A feature of the invention is the provision of a small retrofocus type super wide-angle objective lens system with a front divergent lens group A and a rear convergent lens group B. said front divergent lens group A consisting of front and rear lens groups A, and A said front lens group A, consisting of a positive meniscus first component L, that has its object side a convex surface and two negative meniscus second and third components L and L said rear lens group A consisting of a positive lens fourth component L, and a negative meniscus fifth component L and said rear convergent lens group B consisting of two positive lens sixth and seventh components L and L,. a negative lens eighth component L,,. and two positive lens ninth and tenth components L and Lm. and which is defined by the following three conditions. i.e.

ond and third components L,. L: and L fis an overall focal length ofthe total lens system. ris a radius of curvature of the rear surface of the first component L,. and 2d,, is the sum of the air spaces and axial thicknesses of the sixth component L, to the tenth component L of the rear convergent lens group B.

For a better understanding ofthe invention. the same will be explained by reference to the accompanying drawings. in which:

FIG. 1 shows in cross-section one embodiment of the small retrofocus type super wide-angle objective lens according to the invention;

FIG. 2 shows in cross-section another embodiment of the small retrofocus type super wide-angle objective lens according to the invention;

FIGS. 3a to 3fshow aberration characteristic curves of the embodiment shown in FIG. I; and

FIGS. 4a to 4d show aberration characteristic curves of the embodiment shown in FIG. 2.

Referring to the drawings. the small retrofocus type super wide-angle objective lens according to the invention is shown in HO. 1 in which A designates a front divergent lens group which consists of front and rear groups A, and A:. B shows a rear convergent lens group. The front group A, consists of a positive meniscus first component L, that has its object side a convex surface r, and two negative meniscus second and third components L- and L The rear group A consists of a positive lens fourth component L and a negative meniscus fifth component L,-,. The rear convergent lens group B consists of two positive lens sixth and seventh components L. and L,. a negative lens eighth component L,, and two positive ninth and tenth components L,, and L,,,. If. the composite focal length of the front divergent lens group A is made about -0.7 times the overall focal length of the total lens system and the refractive power of each of the front and rear groups A and B is made high for the purpose of maintaining a long back focal length. the negative distortion and astigmatisms become large. In order to obviate such disadvantage. the front group A, of the front divergent lens group A consists of the first. second and third components L,, L and L and the rear group A, consists of the fourth and fifth components L, and L and the refractive power of each of these components is made small and provision is made of a positive lens as the front lens of the front group A, another positive lens as the front lens of the rear group A of the front divergent lens group A. thereby correcting the above mentioned negative distortion and astigmatisms. In addition, the

sum 2d,, of the air spaces and axial thicknesses of the I optimum performance will hereinafter be described.

The condition l determines a ratio between the refractive power of the front group A, and the rear group A, of the front divergent lens group A. If the composite focal length f, of the front group A', distant from the diaphragm is made smaller than the composite focal length f. of the rear group A- the back focal length of the lens system can be made long. but the astigmatisms and negative distortion become increased. Conversely. if the composite focal length f of the front group A. is made larger than the composite focal lengthf of the rear group A the back focal length of the lens system could not be made long and the diameter of the front lens becomes large. If fILZZX/f-F, is made larger than the upper limit 0.8. the back focal length becomes shorter than a given length. "fuzz/f is smaller than the lower limit 0.2. the negative distortion becomes considerably large.

The condition (2) is indispensable to correction of the astigmatisms and negative distortion caused by that value off /f approaches to the lower limit 0.2. If the radius of curvature rof the rear surface of the first component L exceeds the upper limit w and hence the r surface becomes concave toward the object side of the system. the negative distortion can easily be corrected. but the angles of incidence and projection of the main light rays with respect to the rsurface become large to produce higher degree of aberrations. If ris made smaller than the lower limit 5f. it becomes difficult to correct the astigmatisms and negative distortion. I

The condition (3) makes use ofa continuation of the divergence of light rays caused by the front divergent lens group A up to the rear convergent lens group B except a part thereof. The condition (3) is necessary to maintain the back focal length long. If 2d,, is smaller than the lower limit 0.8f. it becomes impossible to keep the desired value of back focal length. Under such condition. if it is desired to make the back focal length long. the refractive power of the front divergent lens group A should be stronger or the refractive power of the rear convergent lens group B should be proportioned such that the refractive power of the rear side lens thereof is stronger than that of the front side lens. In either of these cases. there are produced the negative distortion and spherical aberrations and hence is not desirous. If 2d,, exceeds the upper limit the diameter of the front lens and overall length of the system become large and hence cause inconvenience for users.

It is preferable to arrange the positive lens sixth and seventh components L and L face to face with a diaphragm therebetween and to define the ratio of the refractive powers of these two components by 0.3 f /f 1 in order to make the back focal length long and prevent the coma from being produced.

In accordance with the present invention. the front lenses of groups A and A- of the front divergent lens group A comprise positive lenses. respectively. and as a result. the meridional image surface becomes considerably shifted to the positive direction when the system is focussed to the short distance. Thus. for short distance photographic purposes. it is preferable to move the seventh and eighth components L and L,. in unison to change 11 and (I with d d constant. thereby correcting the inclination of the meridional image surface.

In FIG. 2 is shown another embodiment of the invention. In the present embodiment. the positive lens LII fourth component L represented in FIG. I by a positive singlet lens is a positive doublet lens, the positive lens sixth and seventh components L and L represented in FIG. I by positive doublet lenses are positive singlet lenses. respectively. and the negative lens eighth component L,. represented in FIG. '1 by the negative singlet lens is a negative doublet lens.

The invention will now be described with reference to the following examples.

EXAMPLE I In FIG. I is shown the construction of the lens system of the present embodiment whose numerical values. based upon a numerical value of mm for the overall focal length. are substantially as given in the following table 1:

Table I -fi=l00. 2w=l00 Thicknesses Radii and Lens r, to r air spaces n to 71,-: u. to 11,

(1 to d .fIL'iI f 0.573

The Seidel aberration coefficients of the lens system of the present embodiment are given in the following table 2:

Table 2 Spherical Lens aberrations (omus Astigmatisms Distortion Petlval sum L 0.0026 0.0319 0.0093 0.4462 0.0918 0.0000 0.0470 -0.0007 0.77l'l3 0.0362 L. 0.0152 0.0270 0.0102 0.3433 0.2300 I.I763 0.0l04 0.1550 0.0699 '0.5I01 L 0.2093 0.0976 0.1429 0.1831 01707 I 2.68Z6 --0.0025 -0.0821 0.(I127 0.4130 L, 06437 0.1946 0.3539 0.1446 0.0684 -0.ZOX6 0.21X7 0.Z136 0.l239 0.0000 L,-, 3.3690 0.1150 0.6223 0.0951 0.4004 Z8.4125 0.0005 0.1I97 0.0032 -0.7571 L 11.151161 0.11427 1.4276 0.0649 0.3249 5.Il l30 ---0.0002 0.03 10 0.0004 0.0693 0.5Z80 0.27X1 0.3l 32 0. 1931 0.0120 1. 1.7362 0.3846 0x171 0.2103 0.0836 3.3116 0.0071 0.1529 0.0036 0.0708 7.6039 0.1209 0.95KX 0.0521 0.1910 L. Z.Z91I 0.I634 0.6119 0.0906 -0.I760 4.7648 -0.7l 97 1.939X 0.4I38 0.2367 L 0.4129 0.3192 0.3630 0.2617 70.0215

8.7127 0.225 0.-H23 0.(12(l3 0.3772 L 0.69 1 6 0.0909 0.1507 0.0702 0.102X 12.293 7 0.00711 0.3101 0.1073 0.2817 Sum 3.5302 0.0056 0.1400 0.2815 0.0916

Various aberration characteristic curves of the present embodiment are shown in FIGS. 3a to 3f. FIG.

Table 3 Continued 00. =100" shows the sphencal aberrat1ons. FIG. 3b the ast1gmag 'g f I tisms, FIG. 30 the distortion. and FIG. 3d the comas. Lens ifadii spaces n, to m: in to 1/ r In the present embod1ment. for short distance photo- 1 o d1 to d2 graphic purposes. the seventh and eighth components 7 L and L" are moved in unison to change d and 11 L1 -58.96 86 I 67 i7 with d +d kept constant such that d =7.96 and 30 101.01 11 659 in order to correct the inclination of the me- 476 ridional image surface. In FIG. 3e are shown the astig- 113;; L755; 37I5| matisms at one-fortieth times when the seventh and 1774415 1091 1814 V19 eighth components L and L, are moved in unison as -1 345 34 described above. In FIG. 3f are shown those when the H 7| seventh and eighth components L; and L, are not L5 546 M968 5563 moved in unison. 9 88 As seen from these aberration characteristic curves 1607/6 shown in FIGS. 30 to 3f, the present embodiment is ca- 0 485 m 59-59 156733 43-83 pable of significantly correcting the various aberrations 13m 6411.73 throughout F/3.5 and p1cture angle 100 L7 3M0 M398 3458 EXAMPLE 2 9944 H2 137.99 In FIG. 2 1s shown the c0nstruct1on of another em- 4; 5.46 M04 4M5 bodiment of the invention whose numerical value of L1 l09.12 z Hm N 4 100 mm for the overall focal length. are substantially 25134 as given in the following table 3: H 5.73

L,, 13.10 1.618 63.38 94.77 3 6.82 Table 968.2()

L, 16.10 1.6111 63.38 #100. 2m=100 1 19.64 1 Thicknesses Radii and Lens r, to rair spaces 11 to 11,-, v, to u d, to 11 1.09 156.51 The Se1de1 aberratlon coefficlents of the lens system 74 M ofthe present embodiment are given in the following l 26.74 table 4:

Table 4 Spherical Lens aberrations Comas Astigmatisms Distortion Petzval sum Table 4-Cont1nued Spherical Lens aberrations ('omas Astigmatisms Distortion Petzval sum 1. 0.1775 0.1017 0.1343 0.1922 0.1522 -Z.-l047 0.00-10 0.09K 0.0I61 41.3901 1., 0.7696 0.1709 0.3627 0.1273 0.0992 0.0003 0.0069 0.0015 0.0123 0.00JZ -0. I414 0.ZOX0 -0.17I -0.2457 0.0054 I. 2.7476 0.11414 0.5616 0.1033 0.39011 '-l.4392 (1.00l2 0. l 7 14 -0.0052 0.7JIX I... 6.6442 0. 19-16 1.1369 0.0711 0.2212 -0.0763 0. 1X79 0.l197 0.l995 0.06014 1; 0.7297 0.2949 0.4639 0.2250 0.0591 I 1.1612 0.1397 l.' 4l 5 0.05X9 0.3866 L, 6.Z-l50 0. 1581 0.9936 0.0756 0.3 I 73 0.0061 -0.0000 0.0005 0.0000 "0.0003 4.31Xl 0.1 437 -|.90l 7 0.4497 0.1736 L,, 0.2145 0.3129 0.2591 0.2693 0.0X99 5.2414 0.0241 0.3551 0.0l8-1 0.3959 I. I 0.()l60 0.0396 0.0251 0.1233 0.03X8 14.1510) 0.0000 0.0076 0.0002 0.3136 Sum 3.0645 0.0I49 0.0961 0.1639 0.0979

Various aberration characteristic curves of the prescnt embodiment are shown in FIGS. 4a to 4d. FIG. 4a shows the spherical aberrations. FIG. 4b the astigmatisms. FIG. 4r the distortion. and FIG. 4d the comas.

As seen from these aberration characteristic curves shown in FIGS. 4a to 4d. the present embodiment is capable of significantly correcting the various aberrations throughout F/3.5 and picture angle 100.

What is claimed is:

l. A small retrofocus type super wide-angle objective lens system with a front divergent lens group A and a rear convergent lens group B. said frontdivergent lens group A consisting of front and rear lens groups A. and

A said front lens group A consisting of a positive meniscus first component L that has its object side a convex surface and two negative meniscus second and third components L and L,, that have their object sides convex surfaces; respectively, said rear lens group A consisting of a positive lens fourth component L that has its object side a convex surface. and a negative meniscus fifth component L,-, that has its object side a convex surface. and said rear convergent lens group B consisting of a biconvex positive lens sixth component L that has its object side a convex surface having a larger curvature. a positive biconvex seventh component L that has its object side a convex surface having a smaller curvature. a negative lens eight component L and two positive meniscus lens ninth and tenth components L, and L that have their image sides convex surfaces. respectively. and which is defined by the following three conditions. i.e.,

where f is a composite focal length of the first, second and third components L L and L fis an overall focal length of the total lens systems r is a radius of curvature of the rear surface of the first component L and 2d,, is the sum of the air spaces and axial thicknesses of the sixth component L to the tenth compo nent L of the rear convergent lens group B.

2. A small retrofocus type super wide-angle objective lens system as claimed in claim 1, wherein said sixth and seventh components L and L; are arranged face to face with a diaphragm therebetween and the ratio of the refractive powers of said two components is defined y 3. A small retrofocus type super wide-angle objective lens system as claimed in claim 1, wherein the seventh and eight components L and L are positioned on the object side for focusing the lens system to the short distance with d +d constant.

4. A small retrofocus type super wide-angle objective lens system as claimed in claim 1, wherein f=l00 mm and 2w=l00 and r, to r d to d n, to n and v, to v are defined by the following values:

Thieknesses Radii and Lens It, to a v, to a r to a air spaces (l to d 

1. A small retrofocus type super wide-angle objective lens system with a front divergent lens group A and a rear convergent lens group B, said front divergent lens group A consisting of front and rear lens groups A1 and A2, said front lens group A1 consisting of a positive meniscus first component L1 that has its object side a convex surface and two negative meniscus second and third components L2 and L3 that have their object sides convex surfaces; respectively, said rear lens group A2 consisting of a positive lens fourth component L4 that has its object side a convex surface, and a negative meniscus fifth component L5 that has its object side a convex surface, and said rear convergent lens group B consisting of a biconvex positive lens sixth component L6 that has its object side a convex surface having a larger curvature, a positive biconvex seventh component L7 that has its object side a convex surface having a smaller curvature, a negative lens eight component L8, and two positive meniscus lens ninth and tenth components L9 and L10 that have their image sides convex surfaces, respectively, and which is defined by the following three conditions, i.e.,
 2. A small retrofocus type super wide-angle objective lens system as claimed in claim 1, wherein said sixth and seventh components L6 and L7 are arranged face to face with a diaphragm therebetween and the ratio of the refractive powers of said two components is defined by
 3. A small retrofocus type super wide-angle objective lens system as claimed in claim 1, wherein the seventh and eight components L7 and L8 are positioned on the object side for focusing the lens system to the short distance with d13+d18 constant.
 4. A small retrofocus type super wide-angle objective lens system as claimed in claim 1, wherein f 100 mm and 2 omega 100* and r1 to r22, d1 to d21, n1 to n12 and upsilon 1 to upsilon 12 are defined by the following values:
 5. A small retrofocus type super wide-angle objective lens system as claimed in claim 1, wherein f 100 mm and 2 omega 100* and r1 and r22, d1 to d21, n1 to n12 and upsilon 1 to upsilon 12 are given by the following values: 